EP0186686B1

EP0186686B1 - Vibration dampening device for sporting rackets

Info

Publication number: EP0186686B1
Application number: EP85902891A
Authority: EP
Inventors: Edward D. Krent; Nicholas B. Paffett
Original assignee: Individual
Current assignee: Individual
Priority date: 1984-05-30
Filing date: 1985-05-28
Publication date: 1990-11-22
Anticipated expiration: 2005-05-28
Also published as: US4609194A; CA1250329A; WO1985005556A1; EP0186686A1; AU4400585A; DE3580660D1; EP0186686A4; JPS61502235A

Abstract

A vibration dampening device (10, 70, 76, 80, 86, 90) for use with hand held sporting rackets (15), particularly tennis rackets, having a face or striking surface (15) formed of two intersecting sets of parallel strings (16, 18). The device of this invention comprises a block of viscoelastic foam which is compressed and inserted between the strings on the striking surface. This block of foam in preferably in the shape of a cylinder and when it is inserted between two, adjacent parallel strings it assumes a generally spherical shape. Typically, this compressed block engages four adjacent strings of both sets of strings or three strings and the racket frame. This block may be placed at various positions on the racket striking surface, and significantly reduces vibrations created in the racket by the striking of a projectile, such as a ball. The device may be constructed of various combinations of different types of foam, and may have any desired color or design.

Description

This invention relates generally to a vibration dampening device, and more particularly to a vibration damping device fitted to a hand held sporting racket having a strung striking surface defined by first and second sets of generally parallel strings that intersect one another in a frame.
For most strung hand held sporting rackets, the intersecting sets of parallel strings are enclosed by an oval frame with a handle. One set extends generally parallel to the handle and may be called the longitudinal strings, while the other set extends generally transversely of the handle and may be called the transverse strings. In such rackets, vibrations are produced in the racket face when a projectile is struck. These vibrations are most noticeable in rackets used in playing games involving a ball, particularly tennis. The vibrations are most severe when the ball does not strike the racket face in the center thereof, but strikes it at a distance spaced from the center or when the hit is not considered to be a "solid" hit. Initially, rather large vibration is detected in the racket face and this initial vibration is followed by a series of smaller vibrations which eventually die out with time. Such vibrations are transmitted generally along the transverse and longitudinal strings of the racket, to the frame surrounding and holding the strings, and eventually down the racket handle to the hand and then the arm of the player. The more one plays, the greater is the exposure to such vibrations. It has been shown that a player who has been subject to extensive periods of racket-induced vibrations can sustain injury to his or her arm. Thus, it is considered desirable to reduce such vibrations both for the comfort of the player and for the protection of the player.
In recent years, the use of composite racket constructions and other advanced technologies has allowed the tension of the racket strings to be increased to levels of 334 Newtons (75 pounds) or more. These higher tensions produce greater and more sustained vibration levels in the racket face and also a greater transfer of vibrations to the handle.
In the past, most efforts at reducing these vibrations have been directed towards the racket construction. Such efforts have included changing the structural material of the racket, and in recent years, fibrous materials such as carbon fibers and boron fibers have been added to the racket head and handle structure. Some previous efforts at reducing vibrations by modifying the racket structure are shown in United States Patents Nos. 3,941,380 and 2,732,209. However, even with these improved racket constructions, vibrations still persist. In addition, different types of racket strings are known to inhibit vibrations better than others. In particular, strings made of natural catgut have a lower tendency to produce vibrations than plastic strings. However, other considerations enter into the choice of materials for the racket and for the strings, and often players prefer materials for higher performance which do not necessarily produce a lower level of vibration.
Another device for dampening the vibrations in the racket strings is shown in United States patent No. 4 180 265. In this device, two strings are coupled together by a device which interlocks them. However, the device shown in this patent has not been entirely successful in reducing vibrations in rackets, particularly in tennis rackets. In addition, the device shown in United States Patent No. 4 180 265 is sometimes difficult to attach to the racket face, and can interfere with the flight of the ball if struck by the ball.
Another dampening device is shown in. FR-A-1 398 833, which comprises a block formed of a rubber or silicone resin which is inserted between the strings of a racket in the striking surface thereof, to contact strings of the two intersecting string sets in order to produce dampening.
It is an object of this invention to provide a vibration dampening device for or in a sporting racket having a strung striking surface, which performs in a manner superior to prior art vibration dampening devices.
The present invention is characterised in that the block inserted into the striking surface is formed of a highly resilient foam which is compressed and presses outwardly against the contacted strings of the first and second sets.
The invention is also characterised in that the dampening device is formed of two different resilient foam materials having two different chemical compositions, one material having a lower rebound property and a higher dampening property than the other material, said foam materials having a minimum rebound of about 50% to about 60% .
The block need not interfere with the flight of the projectile, and can be placed in a suitable position on the racket face to provide optimal dampening of vibrations.
Preferably, the block is in the shape of a cylinder. A cylindrically shaped device is compressed parallel to the axis of the cylinder, and when inserted between two adjacent, parallel strings, the cylinder assumes a generally spherical shape. Typically, if the block is placed between two longitudinal strings, the two adjacent parallel transverse strings, or one adjacent transverse string and the frame will also be engaged as the block expands under the influence of its own elasticity.
The block may be placed at a suitable position on the racket face, at the discretion of the user, to produce optimal dampening characteristics. One option is to place the block at the center of the racket. In this position, the block also serves as a target and it may be used as a learning device for beginning players. to assist them in placing the ball in the center of the block racket. Another option is to place the block at the bottom, center of the racket (i.e. close to the racket handle) so that the device engaged the lower most tranverse string and the two center longitudinal strings, as well as the bottom edge of the racket frame. Other positions may be selected at the discretion of the playerwhich produce optimal results forthe string type and tension of that particular racket and for that particular player.
A preferred material for the block is an open cell, urethane foam or a composite open and closed cell urethane foam. Such a material has the desired memory and dampening properties. It is also sufficiently light and flexible that it does not affect the flight of the ball if struck by it.
Other variations of the basic device of this invention are possible. Different combinations of higher resilience and lower rebound acoustic elastomer foams may be used in layers. In particular, a sandwich may be formed of higher resilience elastomers in the center of the cylinder extending along the axis thereof and of a lower rebound acoustic material along the outer surfaces of the cylinder. In another embodiment, the top and bottom bases of the cylinder may be formed of a composite open and closed cell acoustic, lower rebound elastomer, while the central portion of the cylinder is formed of a higher rebound, high resilience, open cell elastomer. The lower rebound elastomer produces more dampening, while the higher rebound has greater elasticity and memory to keep the strings under constant pressure.
It has been discovered that the invention produces dampening results far superior to those achieved with all prior art devices, and the block is easily inserted onto and removed from or relocated on the racket face as desired.
The invention will be more fully understood from the following detailed description taken in conjunction with the accompanying drawings, in which:

Figure 1 is a perspective view of a resilient block of foam material for use in the invention;
Figure 2 is a perspective, cutaway view of a portion of a racket face showing the block of Figure 1 when inserted on the racket face;
Figure 3 is a cutaway, perspective view of an alternative embodiment of the block;
Figure 4 is a perspective view of another alternative embodiment of the block;
Figure 5A is a front view of a racket face showing the block of Figure 1 inserted in one position,
Figure 5B is a front view of a racket face showing the block of Figure 1 inserted in another position;
Figure 5C is a front view of a racket face showing the positioning of the two blocks of Figure 1;
Figure 5D is a front view of a racket face showing an alternative position of two blocks of Figure 1;
Figure 6 is a graph showing the performance of an embodiment of the invention in which the horizontal axis is time and the vertical axis is a logarithmic representation of the acceleration in meters per second of the racket face;
Figure 7 is a perspective view of another embodiment of the block;
Figure 8 is a perspective view of yet another alternative embodiment of the block;
Figure 9 is a perspective view of another embodiment of the block;
Figure 10 is a perspective view of an alternative embodiment of the block; and
Figure 11 is a perspective view of a block for a further embodiment of this invention.

Referring now to Figure 1, there is shown a dampening device 10 embodying the invention. Device 10 is a block of compressible viscoelastic foam. Although device 10 may have any desired shape, device 10 preferably has a generally cylindrical shape with a pair of bases 12, and is preferably generally symmetric about a central axis 14 running between bases 12. Device 10 is sufficiently viscoelastic so that it continually returns to its original shape after it has been compressed and also so that it absorbs vibration generated in the racket face. Device 10 should also be sufficiently flexible to permit device 10 to be easily compressed into a small space and sufficiently light weight so that it does not affect the balance of the racket face. A preferred material for forming device 10 of this invention should have the following properties as defined in ASTM Standard D-3574: 1. high compression force deflection (CFD), typically in the range of 240 - 400 Newtons (60 to 100 pounds); 2. low compression set value; and 3. a minimum rebound of 50% to 60% under Test H. Materials which are suitable include an open cell foam, and a composite open and closed cell foam, preferably a urethane foam. However, other types of foam can also be used, such as certain closed cell foams, rubber foams or synthetic rubber foams. The material of device 10 preferably has density in the range of 0.028 to 0.149 gm/cc (1.5 to 8 pounds/ft³) but other density foams also may be suitable if they meet the foregoing requirements.
With reference now to Figure 2, implementation of device 10 will now be described. Atypical racket face 15 having a strung striking surface, such as a tennis racket face, consists of a first set of generally parallel transverse strings 18 and a second set of generally parallel longitudinal strings 16. Strings 16 and 18 are generally at right angles and are interwoven with each other. Strings 16 and 18 extend between and are tensioned on an oval frame 20 which surrounds racket face 15. Only a portion of racket face 15 is shown in Figure 2 for purposes of illustration.
Device 10 is shown in Figure 2 deployed in one exemplary location at the base of racket face 15, in the same position shown in Figure 5A. Although this is a preferred position, other positions are possible as will be described hereinbelow. If cylindrical, device 10 is deployed by first compressing bases 12 toward one another generally along axis 14. When bases 12 are spaced less than the distance between adjacent, parallel strings 16 or 18, device 10 can be inserted into the space therebetween. The memory of device 10 causes it to expand once it has been released and placed between strings 16 or 18. Thus, bases 12 press outwardly against adjacents strings 16 or 18, urging them away from one another. This elasticity of device 10 causes each base 12 to curve around its associated string 16 or 18 so that opposite edges of base 12 nearly touch one another and base 12 almost completely encircles associated string 16 or 18. At the same time, some expansion occurs in a direction perpendicular to axis 14, so that the lateral sides of device 10 also contact adjacent strings 16 or 18 which are generally normal to the strings 16 or 18 associated with bases 12. Also, in the position shown in Fig. 2, device 10 may contact an adjacent portion of frame 20. If device 10 has a cylindrical shape, because of the elastic properties thereof, device 10 assumes a nearly spherical shape when in position between two strings 16 or 18, as shown in Fig. 2. As a result, the wind resistance or drag coefficient of device 10 when in place during use of the racket is minimized. Also, because of the light weight of device 10, little or no weight is added to the racket face and neither the balance of the racket nor the performance thereof is affected.
Device 10 dampens vibrations in racket face 15 by mechanically isolating two transverse strings 18 and at least one longitudinal string 16 or two longitudinal strings 16 and at least one transverse string 18 by pressing against the strings without interlocking them. Because the device presses outwardly and engages at least three and usually four strings of a racket, or three strings and the frame, one device is able to effectively dampen vibrations in both the longitudinal and the transverse strings of the racket face, as well as in the frame of the racket. The foam comprising device 10 traps the vibrations and turns the mechanical vibrational energy into heat energy which is dissipated.
Various suggested positions of device 10 on the racket face are shown in Figs. 5A-5D. As previously indicated, the location of device 10 in Fig. 5A is preferred and is the same as that shown in Fig. 2. In Fig. 5A, device 10 is shown in contact with frame 20, as well as with two spaced strings 16, and adjacent string 18. It is preferred that device 10 be centered on the racket face with regard to strings 16, so that it has the optimum dampening effect. Thus, in a preferred position, bases 12 of device 10 engage the two most centrally positioned longitudinal strings 16 and the lateral sides of device 10 touch the lowermost transverse string 18 and an adjacent portion of frame 20 near handle 21. However, off center positions may also be selected if desired.
Fig. 5B shows another preferred location on racket face 15 for device 10. In Fig. 5B, device 10 is positioned generally in the center of racket face 15. In Fig. 5B, device 10 engages the adjacent, centrally disposed pair of transverse strings 18 and the adjacent centrally disposed pair of longitudinal strings 16. Preferably, bases 12 of device 10 engage longitudinal strings 16; however, device 10 may be positioned so that bases 12 engage transverse strings 18 if desired. In this manner, device 10 mechanically isolates four adjacent strings by vibration absorbing means, thus dampening vibrations in the entire racket face 15. This position is particularly suggested for beginning players who have difficulty hitting the projectile atthe center of face 15. In the position in Fig. 5B, device 10 serves as a target for the player to assist him in striking the ball or other projectile in play at the center of the racket face 15, and for this purpose, device 10 may be provided with a bright, highly visible color. Since device 10 is highly flexible and light weight, when it is struck by the ball or other projectile in play, device 10 compresses against racket face 15 and does not affect the flight of the projectile and does not alter the manner in which it is struck. In tennis, device 10 in the position of Fig. 5B guides the player and assists in developing proper hand-eye coordination. In addition, device 10 forces the player to strike the ball with the racket when it is in front of the player and with the arm in the proper position so that the likelihood of "tennis elbow" or other joint related injuries is reduced. In addition, because vibrations are damped, the likelihood of formation of injury is further reduced.
Other suggested positions for device 10 are shown in Figs. 5C and 5D. In these examples, the use of two such devices 10 is illustrated, each device being positioned at an opposite side of the racket. In Fig. 5C, the devices 10 are centrally disposed in the longitudinal direction on the racket face 15 and are positioned on opposite transverse sides of racket face 15. In Fig. 5C, devices 10 are centrally disposed in the transverse direction on racket face 15 and are positioned on opposite longitudinal sides of racket face 15. In each instance, device 10 engages or isolates four intersecting strings, two of which pass through the center of the racket face 15, to provide the desired dampening effect.
With reference now to Fig. 6, the significant reduction of vibrations in a racket resulting from the use of device 10 is graphically illustrated. Fig. 6 is a plot of the logarithm of the acceleration of the racket strings measured in m/sec² on the vertical axis versus time in milliseconds on the horizontal axis.
The measurements in Fig. 6 were made by attaching a miniature accelerometer to the throat of a graphite, composite mid-size tennis racket held by a player. For the purposes of measurements in Fig. 6, device 10 was placed roughly in the position shown in Fig. 5A. In each case, a ball was fired at the racket at a distance of 6 meters (20 feet) from a gun having a fixed muzzle velocity. The ball was struck by the player in roughly the center of the racket face under conditions approximating playing conditions. Measurements were then made of the vibrations in the frequency range of approximately 10 Hz to 40 kHz. The signal generated by the accelerometer was passed through a preamplifier, a variable filter in the range of 10 Hz to 100 kHz, a true RMS averager and logarithmic amplifier, and ultimately to a standard storage oscilloscope which supplied the signals indicated with an envelope time constant of .3 milliseconds.
Curve 28 illustrates the resulting vibrations observed on a tennis racket face when it has been struck by a ball and no device 10 has been employed. An initial peak 30 results from the impact of the ball on the strings. Thereafter, the strings continue to vibrate, exhibiting a series of smaller peaks or aftershocks 32, 34, 36 and 38 which are caused by the impact of the ball and which eventually dampen to nearly zero after about fourteen milliseconds. In contrast, curve 26 of Fig. 6 shows the pattern of vibrations resulting from the impact of the ball when device 10 is employed. When the racket strikes the ball, initial peak 40 results which is much smaller than peak 30 of curve 28. Curve 26 is rapidly damped to nearly zero by device 10, and only very small additional peaks 29 are observed. In curve 26, the vibrations are effectively completely eliminated after about four milliseconds. This period of vibrations is about only one-third as long as that observed when device 10 was not employed. In addition, as can be seen from Fig. 6, the magnitude of the vibrations, including both the initial one caused by impact with the ball, and the later aftershocks, are significantly reduced. The aftershocks or peaks 32 and 34 of curve 28 are almost completely missing from curve 26, and are only manifested as a series of very minor blips which are hardly registerable.
Other embodiments of the device 10 are illustrated in Figs. 3, 4, 7, 8, 9, 10 and 11. In each of these embodiments, devices are formed utilizing different foams having different viscoelastic properties. In Fig. 3, a device 50 is shown which has a central cylindrical core 54 and an outer annular shaped portion 52. Core 54 is preferably formed of an acoustic foam which has higher dampening properties and which has lower rebound properties than annular portion 52. Annular portion 52 is typically formed of a material which has high rebound and high resilience characteristics and which has properties falling within the limitations under ASTM standard D-3574 previously set forth. An example of the material which may be used in core 54 is an acoustic polyether which can either be a composite closed and open cell foam or an open cell foam. An example of the material which may be used in outer annular portion 52 is a polyester-polyether foam that has high resilience, and a preferred density of about two to three pounds per cubic foot.
Fig. 4 shows another cylindrical device 60 formed of two different types of foam. Device 60 has a central portion 64 and axially extending segments 62 which are inserted in channels formed in central portion 64. Portion 64 composed of a higher rebound foam than segments 62 which has properties falling within the limitations under ASTM standard D-3574 previously set forth. An example of the foam of portion 64 is the polyester-polyether foam previously referenced. Segments 62 are typically formed of an acoustic foam which has lower rebound properties than portion 64, an example of which is an acoustic polyether. Segments 62 have a generally trapezoidal cross-sectional shape as viewed from base 66, and segments 62 extend along the entire axial length of device 60. Four such segments are shown, although more may be provided.
The devices of both Fig. 3 and Fig. 4 have the desired elasticity and the desired softness so that they do not interfere with the flight of a projectile when hit, and in addition, they are provided with greater vibration absorbing properties 11 because of the inclusion of acoustic foam portions which have greater dampening properties because of the inclusion of acoustic foam portions which have greater dampening properties.
Fig. 7 also shows a cylindrical device 80 formed of two different foams. Device 80 includes a central portion 84 which extends along a diameter in one direction along the entire axial length thereof in the other direction. Disposed on each lateral face of portion 84 is an outer portion 82 which extends the entire axial length of device 80. Portions 82 typically are symmetrical about portion 84 and each have a partially circular cross-section bounded by a chord that does not pass through the center of the circular base of device 80. Portions 82 are formed of a foam which has properties as previously set forth under ASTM standard D-3574, such as a polyester-polyether foam. Central portion 84 is formed of a foam which has lower rebound properties than those of portions 82, such as an acoustic foam made of polyether.
Fig. 8 shows an alternative to the embodiment of Fig. 7. In Fig. 8, cylindrical device 86 is formed of a plurality of axially extending slabs 88. Each slab 88 has a similar thickness and extends the entire axial length of device 86 in one direction. The transverse dimension of each slab 88 is defined by a pair of parallel chords extending across the circular base of device 86. Each slab 88 is typically formed of a different foam, and the rebound characteristics of the foams selected decreases as one moves from the outside of the cylinder towards its center so that slab 89 is formed of a foam having the greatest dampening properties, and slabs 87 are formed of a foam having and the greatest memory and the greatest resilience. A preferred example of the foam used to form slab 89 is an acoustic polyether, while an example of the preferred foam for forming slabs 87 is a polyester-polyether foam.
In Fig. 9, a cylindrical device 70 is shown having three sections. There is a central section 74, and two end caps or discs 72 which are of about equal thickness. Central section 74 is composed of a higher rebound elastomer foam than caps 72 and section 74 typically has the properties previously set forth under ASTM standard D-3574. An example of the material of section 74 is a polyester-polyether foam. Caps 72 are formed of a lower rebound elastomer than section 74, an example of which would be an acoustic polyester. In device 70, the portion thereof which contacts the strings of the racket face is provided with greater dampening properties, while the central portion 74 which biases end caps 72 against the strings has the desired high resilience. In addition, portion 74 is the part of device 70 which would be exposed to a projectile which strikes the racket, and since it has the required high resilience and low weight, the trajectory of the projectile remains unaffected.
Fig. 10 shows an alternative embodiment of the device of Fig. 9. In Fig. 10, device 76 is comprised of a plurality of discs 78 aligned generally perpendicularly of the axis of device 76. Discs 78 are secured to one another, each disc having approximately the same axial thickness and the same circular cross-section. The discs 78 at the ends of device 76 are formed of the lowest rebound foam with the greatest dampening properties. The discs 78 have greater rebound characteristics as one passes from the ends towards the center of device 76, so that the disc formed of the foam with the greatest resilience is disposed at the center of device 76. As a result, the discs with the greatest dampening properties are in direct contact with the strings, while the central portion of the device provides the desired resilience and memory to bias the end discs against the strings. Also, because of the resulting spherical shape of device 76 when inserted, the central portion of device 76 is the part which is struck by the projectile and also is the part which has the resilience required to not affect the path of the projectile.
Devices 10, 50, 60, 70, 76, 80 and 86 each typically has the same shape and dimension and is employed in the same manner on the racket face. As indicated, a preferred shape is cylindrical with the optimal size being a cylinder of about 7/8 inch diameter. However, good results can be achieved with a cylinder as small as 13 mm (1/2 inch) diameter or a cylinder as great as 26 mm (1 inch) in diameter. If the cylinder becomes too large, much larger than about 26 mm (1 inch) diameter, it begins to exert a measurable amount of drag on the racket face and is much less desirable. If the cylinder is less than about 13 mm (1/2 inch) in diameter, it is not sufficiently large to contact all four of the intersecting strings of the racket face. A typical axial length of the cylinder would be about 39 mm (1-1/2 inches), although this dimension could be shorter or longer depending upon the resilient characteristics of the foam used, and depending upon the type of racket with which the device is to be employed.
With reference to Fig. 11, another embodiment of the vibration dampening device of this invention is shown. Device 90 includes a central portion 92 and two outer portions 94 affixed thereto. Both central portion 92 and outer portions 94 are formed of a compressible, viscoelastic plastic foam. Central portion 92 is adapted to be compressed and inserted into the space defined by two adjacent, parallel transverse strings intersecting two adjacent, parallel longitudinal strings. Typically, central portion 92 would intersect or engage each of the four strings. Outer portions 94 are shown in Fig 11 as extending beyond the lateral surfaces of central 1 portion 92, but portions 94 also could have a cross-sectional area less than that of central portion 92. Outer portions 94 do not press against the strings of face 15 and are not in the plane thereof. In the embodiment as shown in Fig. 11 where portions 94 extend beyond the lateral edges of central portion 92, portions 94 overlie and presumably touch adjacent strings of racket face 15. Portions 94 could have any desired shape or configuration, such as the heart shape shown in Fig. 11. Dampening of string vibrations is provided both by the effect of central portion 92 pressing outwardly to engage adjacent strings, and by the effect of outer portions 94 touching strings on face 15. Preferably, central portion 92 is formed of an acoustic foam which has higher dampening properties and lower rebound properties than the material forming outer portions 94. The preferred position on the racket face 15 for device 90 is that shown in Fig. 5A, although any of the other suggested positions would also be acceptable.
The foregoing invention has numerous features and characteristics which render it superior to prior devices. One important characteristic is that the device may be easily attached to and removed from the racket after the racket has been strung. Each racket must be individually tailored to the needs of the particular player and his game. Every racket is somewhat different from other racket, depending on how it is strung and depending upon its particular construction. The characteristics of a particular racket which would affect the positioning of the device, or the number of devices used, or the foam composition of the device are the balance, the string tension, the type of game being played, whether the user is serving or volleying, and the vibration characteristics of the racket frame and materials. Thus, this invention allows a player to empirically determine for himself which position he prefers, which particular type of device he prefers, and which device performs best for that particular racket. In addition, should the device become worn out, it is readily replaceable.
Another advantage of this particular device is that it may be placed in the center of the racket to be used as a target, particularly for beginners, to allow the projectile or ball to be struck directly in the center of the racket face. Probably the most significant feature of this invention is its superior vibration dampening effects.

Claims

1. A hand-held sporting racket for striking a moving projectile, including a frame (20) strung with first and second sets of generally parallel strings (16, 18), the strings of the first set (16) intersecting the strings of the second set (18) transversely to define a projectile striking surface (15); and at least one block (10) inserted into said striking surface in contact with at least one string of each of said sets for dampening vibrations in the striking surface, characterised in that said block (10) is formed of a highly resilient foam which is compressed and presses outwardly against the contacted strings of said first and second sets.

2. A racket as recited in claim 1 wherein prior to insertion said block (10) is generally in the shape of a cylinder having a base (12) at each end and a central axis (14) extending between the bases.

3. A racket as recited in claim 2 wherein said block (10) has assumed a generally spherical shape upon insertion between the strings.

4. A racket as recited in any preceding claim wherein said block (10) is composed of at least two foams having different rebound properties.

5. A racket as recited in claim 4 wherein at least one of said foam materials is formed of a urethane, open cell foam.

6. A racket as recited in claim 4 or 5 wherein said foam materials are characterised by a low compression set value, and a minimum rebound of about 50% to about 60%.

7. A racket as recited in claim 4, 5 or 6 wherein prior to insertion said block (10) has opposite ends spaced from one another, and wherein one of said materials (54) is disposed in the center of said block and the other of said materials (52) completely surrounds said one material between said opposite ends.

8. A racket as recited in claim 4, 5 or 6 wherein said block (10) is elongate and has opposite ends spaced from one another in the longitudinal direction thereof, wherein said opposite ends (72) of said block are formed only of one of said materials and wherein the remainder (74) of the block is formed of the other of said materials.

9. A racket as recited in claim 4, 5 or 6 wherein said block (10) is formed of a central portion (84) and two outer portions (82), each of said central and outer portions extending between opposite ends of said block, said central portion being formed of one of said materials and said two outer portions being formed of the other of said materials.

10. A racket as recited in claim 4, 5 or 6 wherein said block (10) comprises a plurality of segments (64) embedded in the outer surface thereof and extending between opposite ends of the block, said segments being formed of one of said materials and the remainder (74) of the block (10) being formed of the other of said materials.

11. A racket as recited in claim 4, 5 or 6 wherein said block (10) is formed of a plurality of stacked layers (78) of foam, each layer extending across said device generally parallel to opposite ends of said device, each layer being formed of a foam of different rebound and dampening properties.

12. A racket as recited in claim 11 wherein layers disposed near the center of said block spaced from said opposite ends have the greatest rebound properties and wherein layers disposed near said opposite ends of said block have the greatest dampening properties.

13. A racket as recited in claim 4, 5 or 6 wherein said block is formed of a plurality of generally parallel, stacked layers (87, 88, 89) each layer extending between opposite ends of said block, layers disposed near the transverse center of said device having greater dampening properties than layers disposed near the transverse edges of said block.

14. A racket as recited in any one of claims 4 to 13 wherein said two different foam materials have two different chemical compositions, one material having a lower rebound property and a higher dampening property than the other of the materials.

15. A racket as recited in any preceding claim including a handle (21) having a first end adapted to be gripped by the hand of a player and a second end coupled to the frame (20), the strings (16) of the first set extending longitudinally of the racket and the strings (18) of the second set extending transversely thereof.

16. A racket as recited in claim 15 wherein said block (10) is disposed at the transverse center of said striking surface (15) and adjacent said frame (20) where said frame is coupled to said second end of said handle (21).

17. A racket as recited in claim 15 wherein said block (10) is disposed at the transverse and longitudinal center of said striking surface (15).

18. A racket as recited in claim 15 including a second compressed, highly resilient foam block (10) inserted into said striking surface (15) and spaced from the first mentioned block (10).

19. A racket as recited in any one of claims 15 to 18 wherein the or each said highly resilient foam block (10) is disposed between two adjacent longitudinal strings (16).

20. A racket as recited in any one of claims 15 to 19 wherein the or each said highly resilient foam block (10) is disposed between two adjacent transverse strings (18).

21. A device in form of a block (10) for dampening vibrations in the striking surface (15) of a stringed hand-held sporting racket being inserted between the strings thereof, said dampening device being characterised in that said device is formed of two different, resilient foam materials (52, 54; 62, 64; 82, 84; 87, 88, 89; 72, 74; 78; 92, 94), having two different chemical compositions, one material having a lower rebound property and a higher dampening property than the other material, said foam materials having a minimum rebound of about 50% to about 60%.

22. A device as recited in claim 21, wherein at least one of said foam materials is formed of a urethane, open cell foam.

23. A device as recited in claim 21 or 22 wherein said device is generally in the shape of a cylinder having a base at each end and a central axis extending between the bases.

24. A device as recited in any one of claims 21 to 23 wherein said device has opposite ends spaced from one another, and wherein one of said material (54) is disposed in the center of said device and the 1 other of said materials (52) completely surrounds said one material between said opposite ends.

25. A device as recited in any one of claims 21 to 23 wherein said device is elongate and has opposite ends spaced from one another in the longitudinally direction thereof, wherein said opposite ends (72) of said device are formed only of one of said materials and wherein the remainder (74) of said device is formed of the other of said materials.

26. A device as recited in any one of claims 21 to 23 wherein said device is formed of a central portion (84) and two outer portions (82), each of said central and outer portions extending between opposite ends of said device, said central portion being formed of one of said materials and said two outer portions being formed of the other of said materials.

27. A device as recited in any one of claims 21 to 23 wherein said device comprises a plurality of segments (64) embedded in the outer surface thereof and extending between opposite ends of said device, said segments being formed of one of said materials and the remainder (74) of said device being formed of the other of said materials.

28. A device as recited in any one of claims 21 to 23 wherein said device is formed of a plurality of stacked layers of foam (78), each layer extending across said device generally parallel to opposite ends of said device, each layer being formed of a foam of different rebound and dampening properties.

29. A device as recited in claim 28 wherein layers disposed near the center of said device spaced from said opposite ends have the greatest rebound properties and wherein layers disposed near said opposite ends of said device have the greatest dampening properties.

30.A device as recited in any one of claims 21 to 23 wherein said device is formed of a plurality of generally parallel, stacked layers (87,88,89), each layer extending between opposite ends of said device, layers disposed near the transverse center of said device having greater dampening properties than layers disposed near the transverse edges of said device.